Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.1.1.8 (cholinesterase)
12,691 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Previous results on butyrylcholinesterase-catalyzed hydrolysis of o-nitrophenylbutyrate in the presence of soman, an irreversible inhibitor of cholinesterases, suggested that reversible binding of soman preceding enzyme phophonylation induced a new enzyme conformational state (E'). The purpose of the present study was to determine whether this effect depends on soman itself or is dependent on the presence and nature of substrate or ligand. First, we examined the effect of amiloride, a reversible cholinesterase effector, upon the butyrylcholinesterase-catalyzed hydrolysis of nitrophenyl esters. The effect of amiloride was found to be dependent on the position ortho or para of the substrate nitro group: amiloride acts as a non-linear reversible activator of p-nitrophenyl ester hydrolysis and as a non-linear reversible inhibitor of o-nitrophenyl ester hydrolysis. Second, the effect of amiloride upon hydrolysis of o/p-nitrophenylbutyrate was also studied under perturbing conditions, i.e., as a function of pressure (1-1600 bar) in the presence and absence of soman. Results show that the effect of reversible soman binding on butyrylcholinesterase activity in the presence of amiloride depends on the position of the substrate nitro group and amiloride concentration. Molecular modelling suggests that the presence of amiloride determines the orientation of ortho- and para-nitrophenyl esters in the active-site. gorge. The nitro group of o-nitrophenylbutyrate interacts with the oxyanion hole via hydrogen bonds and its phenyl ring interacts with amiloride whose heterocycle faces Trp-82. The nitro group of p-nitrophenylbutyrate does not interact with the oxyanion hole but points towards Tyr-332; the phenyl ring of p-nitrophenylbutyrate interacts with amiloride but there is no steric constraint on the acyl chain. Thus, the network of interactions in ternary complexes is tighter with o-nitrophenylbutryate as the substrate. There is no evidence for the existence of amiloride and/or soman-induced E' state when p-nitrophenylbutyrate is the substrate. On the other hand, reversible binding of amiloride and/or soman induces new active conformational states that may be either binary (or ternary) enzyme-ligand complex or new free enzyme conformation resulting from long-lived ligand-induced enzyme conformational change when o-nitrophenylbutyrate is the substrate. These ligand-induced states are stabilized by high pressure.
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PMID:Substrate dependence of amiloride- and soman-induced conformation changes of butyrylcholinesterase as evidenced by high-pressure perturbation. 761 49

Acetylcholinesterase has an action in the central nervous system, independent of hydrolysis of acetylcholine. This study explored the possible interaction between the two molecules: the effects of acetylcholinesterase on the autoxidation of the catecholamine were tested, and, in turn, modification of the catalytic activity of the enzyme by products of dopamine oxidation were studied. Acetylcholinesterase selectively inhibited the speed of quinone production from dopamine as well as accumulation of hydrogen peroxide, whilst the rate of generation of superoxide was increased. Analysis of absorption spectra revealed the formation of a new product, which appeared after mixing acetylcholinesterase and dopamine in neutral pH. In all cases, butyrylcholinesterase was ineffective. Incubation of acetylcholinesterase in the presence of dopamine resulted in a significant decrease in the catalytic activity of the enzyme. The effects of application of preparations modifying autoxidation of dopamine (SOD, catalase, peroxidase) suggested that inactivation of the enzyme occurred as a result of the direct interaction of a quinone and/or semiquinone oxidation product with enzyme, as opposed to any effects of reactive oxygen species. Because acetylcholinesterase and dopamine are co-released from the neurons degenerating in Parkinson's disease, a direct chemical interaction between these two molecules could have significance both for the normal functioning of the substantia nigra and for related pathological states.
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PMID:A possible interaction between acetylcholinesterase and dopamine molecules during autoxidation of the amine. 774 5

To distinguish between sequence-dependent effects and non-specific cytotoxicity of phosphorothioate antisense oligonucleotides (AS-oligos), we introduced AS-oligos blocking expression of 2Hs, the Homo sapiens cell division controller cdc2 kinase, its hematopoietically expressed homolog CHED, and the acetylcholine-hydrolyzing enzyme butyrylcholinesterase (BCHE) into primary murine bone marrow (BM) culture. Antisense oligonucleotides were fully phosphorothioated (Ts) or prepared with three phosphorothioate groups at their 3' termini (S3). Each of these oligos could cause reductions in colony counts either as a result of its sequence-dependent biological capacity or due to sequence-independent cytotoxicity. The Ts and S3 forms of the matching sense oligo, S-BCHE, served for comparison. The S3 forms of AS-2Hs, AS-BCHE, and S-BCHE caused more limited drops in colony counts than their Ts counterparts, reflecting lower cytotoxicity. When incubated with electroblotted BM proteins, Ts but not S3 oligos intensively labeled two protein bands. Moreover, 5'-end 32P-labeled (Ts) S-BCHE labeled nuclear proteins in situ in small, mitotic cells, suggesting correlation between oligo-protein interactions and the sequence-independent cytotoxicity of Ts AS-oligos. Extension of the apparently nontoxic AS-CHED by two adenosine residues at the 3' end, creating a potential for intramolecular hydrogen bond formation, resulted in increased toxicity. These findings recommend the use of nonlooped, partially phosphorothioated oligos for the modulation of hematopoiesis.
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PMID:Use of partially phosphorothioated "antisense" oligodeoxynucleotides for sequence-dependent modulation of hematopoiesis in culture. 784 88

A potentiometric method for cholinesterase inhibitor analysis based on mediatorless bioelectrocatalysis has been developed. The method includes coimmobilization of three enzymes, butyrylcholinesterase, choline oxidase and peroxidase, on composite carbon electrodes. Catalytic hydrolysis of butyrylcholine and subsequent catalytic oxidation of choline result in the formation of hydrogen peroxide leads to a shift in the electrode potential. The detection limit for trichlorfon analysis is 2 x 10(-13) M. Electrodes remain stable for at least 4 weeks when stored at 277 K.
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PMID:Potentiometric biosensors for cholinesterase inhibitor analysis based on mediatorless bioelectrocatalysis. 868 64

The mechanism of inactivation of cholinesterase (EC 3.1.1.8) by the Cu2+ -ascorbic acid (AsA) system was investigated. Incubation of the enzyme with the Cu2+ -AsA system under aerobic conditions resulted in an irreversible loss of enzyme activity. At low concentrations of Cu2+, the extent of inactivation showed the same dependence in accordance with the extent of oxidation of AsA. Saturation kinetics were observed with respect to the concentration of AsA. No change in the dissociation constant of the enzyme-AsA complex was observed at various concentrations of Cu2+. Catalase at a low concentration partially protected the enzyme from the inactivation, but did not affect the oxidation of AsA. In addition, catalase at a high concentration completely protected both the enzyme from inactivation and the AsA from oxidation. Both thiourea and thiocyanate completely protected the enzyme from the inactivation, while AsA was partially oxidized only in the initial phase. Our proposed mechanism for the inactivation of an enzyme by the Cu2+ -AsA system is as follows. A ternary complex involving the enzyme, Cu2+ and AsA is formed. This is followed by a redox reaction within the complex which generates a superoxide (.O2-) and hydrogen peroxide (H2O2). The H2O2 then reacts with .O2- in a Haber-Weiss reaction producing the hydroxyl radical (.OH). Another role of H2O2 is the conversion of the reduced Cu+ within the complex to Cu2+. Thus, repeated cycles of the redox reaction between the Cu2+ and AsA take place at the same locus, producing multiple .OH, which causes its complete inactivation.
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PMID:Inactivation of cholinesterase by ascorbic acid in the presence of cupric ions: a possible mechanism for the inactivation of an enzyme by the metal-catalyzed oxidation system. 884

Lactoperoxidase, when incubated with increasing amounts of promethazine (P) and promethazine sulfoxide (PO) catalyzes the formation of promethazine sulfoxide accompanied by oxygen consumption. An intermediate radical of PO can be detected by electron spin resonance (ESR). Catalase or superoxide dismutase do not inhibit the reaction while dopamine does. The lactoperoxidase-catalyzed formation of dopaminochrome in the presence of hydrogen peroxide is inhibited by P. Both P and PO inhibit acetyl- and butyrylcholinesterase. Purified enzymes were used throughout the study and horseradish peroxidase but not myeloperoxidase had an activity similar to that of lactoperoxidase.
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PMID:A peroxidase-catalyzed sulfoxidation of promethazine. 951 66

Bienzymatic sensors for the determination of esters of choline were prepared by covalent co-immobilization of cholinesterases and choline oxidase on polymer membranes, obtained by radiation-induced copolymerization of 2-hydroxyethyl methacrylate and glycidyl methacrylate at low temperature. Optimization of the covalent attachment of choline oxidase and acetyl- or butyrylcholinesterase to copolymer was explored. The enzyme-modified polymers were applied on platinum electrodes to form amperometric sensors, based on the electrochemical detection of enzymatically developed hydrogen peroxide. Acetyl-, acetylthio-, butyryl-, and butyrylthiocholine contents in standard solutions were measured, and linear calibration curves were determined. Temperature and pH effects on the electrochemical response are described.
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PMID:Covalently immobilized choline oxidase and cholinesterases on a methacrylate copolymer for disposable membrane biosensors. 985 1

Wild-type human butyrylcholinesterase (BuChE) has a non-Michaelian behaviour showing substrate activation with butyrylthiocholine (BTC) as the substrate. The D70G mutant has a catalytic constant identical to that of the wild-type enzyme, but a 10-fold lower affinity for BTC compared to wild-type enzyme, and it does not exhibit activation by excess BTC under conventional conditions. In the present work it was found that addition of polyols or sugars changed the kinetic behaviour of the D70G mutant with BTC. In the presence of 40% sucrose, the D70G mutant enzyme displayed marked activation by excess substrate. Because D70 is hydrogen bonded to Y332, mutants of Y332 were studied. Mutant Y332F had a behaviour similar to that of wild-type BuChE, whereas mutants Y332A, Y332A/D70G and D70G had negligible substrate activation. The behavior of wild-type, Y332F, Y332A and Y332A/D70G did not change in the presence of high concentrations of sugar. Substrate activation has been explained by binding of a second substrate molecule in the peripheral site at D70. The D70G mutant should be incapable of substrate activation, if D70 were the only residue involved in substrate activation. The ability of the D70G mutant to display substrate activation by medium engineering suggests that other residues are involved in initial substrate binding and activation by excess substrate. Osmolyte-induced change in conformation and/or hydration status of Y332 and other solvent-exposed residues may account for the non-Michaelian behaviour of the D70G mutant.
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PMID:Polyol-induced activation by excess substrate of the D70G butyrylcholinesterase mutant. 998 27

Three different mutations at codons 330 (TTA to ATA), 365 (GGA to AGA) and 515 (CGT to TGT) of human butyrylcholinesterase (hBChE) were identified in a Japanese family. We correlated alterations in in the patient's hBChE activity with possible structural alterations in the three-dimensional structure of hBChE caused by the point mutations. This study was performed using the published computer-generated three-dimensional structure of hBChE based on the structure of acetylcholinesterase. The amino acid substitution at L330I was adjacent to hydrophobic residues that form the channel domain of the active center. This side chain faced the side opposite the active center. The amino acid substitution at G365R was located at the position most remote from the active center, and this substitution site was exposed to the surface of the BChE protein. Alpha-helical structure was present to the active center, and the guanidyl residue of native Arg 515 was hydrogen-bonded to the carboxyl group of Asp 395 in the alpha-helix. These point mutations may cause steric effects on the present patient's hBChE activity. This is the first report of three-dimensional structural analysis performed on the L330I, G365R, and R515C mutations of hBChE.
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PMID:Three point mutations of human butyrylcholinesterase in a Japanese family and the alterations of three-dimensional structure. 1040 29

Wild-type human butyrylcholinesterase (BuChE) and Glu-197-->Asp and Asp-70-->Gly mutants (E197D and D70G respectively) were inhibited by di-isopropyl phosphorofluoridate under standard conditions of pH, temperature and pressure. The effect of hydrostatic and osmotic pressures on the aging process (dealkylation of an isopropyl chain) of phosphorylated enzymes [di-isopropylated (DIP)-BuChE] was investigated. Hydrostatic pressure markedly increased the rate of aging of wild-type enzyme. The average activation volume (DeltaV( not equal)) for the dealkylation reaction was -170 ml/mol for DIP wild-type BuChE. On the other hand, hydrostatic pressure had little effect on the aging of the DIP mutants (DeltaV( not equal)=-2.6 ml/mol for E197D and -2 ml/mol for D70G), suggesting that the transition state of the aging process was associated with an extended hydration and conformational change in wild-type BuChE, but not in the mutants. The rate of aging of wild-type and mutant enzymes decreased with osmotic pressure, allowing very large positive osmotic activation volumes (DeltaV not equal osm) to be estimated, thus probing the participation of water in the aging process. Molecular dynamics simulations performed on the active-site gorge of the wild-type DIP adduct showed that the isopropyl chain involved in aging was highly solvated, supporting the idea that water is important for stabilizing the transition state of the dealkylation reaction. Wild-type BuChE was inhibited by soman (pinacolyl methylphosphonofluoridate). Electrophoresis performed under high pressure [up to 2.5 kbar (1 bar=10(5) Pa)] showed that the soman-aged enzyme did not pass through a pressure-induced, molten-globule transition, unlike the native wild-type enzyme. Likewise, this transition was not seen for the native E197D and D70G mutants, indicating that these mutants are resistant to the penetration of water into their structure. The stability energetics of native and soman-aged wild-type BuChE were determined by differential scanning calorimetry. The pH-dependence of the midpoint transition temperature of endotherms indicated that the high difference in stabilization energy between aged and native BuChE (DeltaDeltaG=23.7 kJ/mol at pH 8.0) is mainly due to the salt bridge between protonated His-438 and PO(-), with pK(His-438)=8.3. A molecular dynamics simulation on the MIP adduct showed that there is no water molecule around the ion pair. The 'hydrostatic versus osmotic pressure' approach probed the importance of water in aging, and also revealed that Asp-70 and Glu-197 are the major residues controlling both the dynamics and the structural organization of the water/hydrogen-bond network in the active-site gorge of BuChE. In wild-type BuChE both residues function like valves, whereas in the mutant enzymes the water network is slack, and residues Gly-70 and Asp-197 function like check valves, i.e. forced penetration of water into the gorge is not easily achieved, thereby facilitating the release of water.
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PMID:Hydration change during the aging of phosphorylated human butyrylcholinesterase: importance of residues aspartate-70 and glutamate-197 in the water network as probed by hydrostatic and osmotic pressures. 1051 Mar 1


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